Transcript Telescopes

Light and Telescopes
The key thing to note is that light and matter interact. This
can happen in four principal ways:
1) emission – a hot object such as the filament in a light
bulb emits visible light
2) absorption – when you place your hand near a light bulb,
your hand absorbs some of the light and heats your hand
3) transmission – some forms of matter (e.g. air, water) allow
light to pass through (where some fraction is also absorbed)
4) reflection/scattering – light can bounce off metal or glass,
or it can bounce in more random directions (such as when
it enounters a cloud of dust)
The purpose of a telescope is to gather as much light
as possible. All things considered, the most important
feature of a telescope is its diameter, because that
stipulates how much light it can collect.
The area (A) of a circle of radius r is p r2 .
Since the diameter (D) of a circle is 2r, the
area of a circle is also equal to p (D/2)2 = p D2 / 4.
The light gathering power of a telescope is related
to the area of the main light collecting objective
(the area of the lens up front or the mirror at the
back end). If you have two telescopes of the same
design, and one has twice the diameter of the other,
the larger telescope has four times the light gathering
power as the smaller one.
The speed of light in a vacuum is a constant (c), roughly
300,000 km/sec. Newton spoke of light as a particle,
and to a certain extent he was right. But it can also
be thought of as waves. A “particle of light” (photon)
can be considered a bundle of waves.
The relationship between the wavelength () and
frequency (f) of light is:
f = c
.
Light visible to our eyeballs has wavelengths between
400 and 700 nanometers, or 4000 to 7000 Angstroms.
Short wavelength light waves have high energies and
long wavelength light has low energy. The energy of
a photon can be calculated as follows:
E =hc/
,
where h is Planck's constant.
High energy photons like UV light, X-rays, and
gamma rays can damage your body. Low energy
waves like radio waves are not harmful.
object
gives off light at
matter spiralling into
black hole
X-rays
very hot stars
Sun-like stars
planets
interstellar hydrogen
ultraviolet/optical
optical/IR
reflected optical + IR
radio
The atmosphere blocks X-rays and gamma rays
from reaching sea level. Some UV light gets through.
Some infrared (IR) light gets through.
High altitude observatories like Mauna Kea are good
sites for optical and IR astronomy because they are
halfway to space. Half of the Earth's atmosphere is
below you.
Two kinds of Telescopes
refractor – primary light gathering element is a
convex lens
reflector – primary light gathering element is a
concave mirror
Blue light is refracted more than red light
As a result, Galileo's refractors suffered from a bad
optical feature. He could not bring all the colors to
focus at the same place.
Refractors
suffer from
chromatic
aberration.
Newton constructed the first reflecting telescope
in 1668. It consisted of a concave primary mirror,
a flat secondary mirror, and an eyepiece at the
side.
The world's
largest refracting
telescope is at
Yerkes Observatory in Williams
Bay, Wisconsin
3 kinds of reflecting telescopes
Each of the 10-m Keck telescopes at Mauna Kea, Hawaii,
has a primary mirror consisting of 36 hexagonal
segments. Signals from the two telescopes have been
combined, simulating a much larger telescope.
In order to make a telescope larger than 8-m in diameter,
it is necessary to have a segmented primary mirror, or
combine the light of several mirrors into one telescope.
The magnification of a telescope is simply the focal
length of the primary lens/mirror divided by the focal
length of the eyepiece:
M =
Fo / Fe
.
So – any telescope can get any magnification! You
just need a very short focal length eyepiece to get
1000 X. However, you are limited by the atmosphere
and the quality of your optics. For a 6-inch diameter
telescope, the effective maximum magnification is
about 150 X.
Review slide
How much light a telescope can gather depends on
the area of the primary light gathering element.
Since area is proportional to the square of the
diameter, two telescopes of different diameters will
have light gathering power that scales with D2.
LGPA/ LGPB = (DA/ DB)2
Thus, for two telescopes of comparable optical
quality at the same location, if one has twice the
diameter of the other, it detects 4 times as many
photons, so can detect fainter stars.
Most mountain observatories are built within
50 miles of the ocean, because it is found that there
is smooth, laminar flow of air. High in the Rocky
Mountains, however, the air is more turbulent.
If a site gives very sharp stellar images, it is said
to have good seeing. At Cerro Tololo, Chile, the
typical seeing is about 1 arc second. At Mauna
Kea, Hawaii, the typical seeing is 0.6 arcsec.
Still, a telescope has a theoretical limit for being
able to resolve detail in astronomical images.
This is because of a property of waves called
diffraction.
At optical wavelengths (550 nm = 5500 Angstroms),
the resolving power of a telescope in arc seconds
is related to the diameter of the telescope in cm as
follows:
 = 13.8 / D
Thus, for a 25 cm diameter telescope, the theoretical
resolving power is 0.55 arcsec. That assumes that
the effects of the atmosphere can be completely
eliminated.
A practical example: what size telescope do you
need to read a license plate from an orbiting satellite?
If a letter is 6 cm in size and the satellite is 200 km
away, a letter subtends an angle of 0.062 arcsec.
You need a 2.2-m telescope with adaptive optics
to have a chance. That is the size of the Hubble
Space Telescope and various spy satellites.
An equatorial mounting can be aligned on the celestial
pole, and the clock drive can turn the telescope at 15
degrees per hour to track on the stars.
This kind of telescope mounting requires computer
control, as both altitude and azimuth change continuously. But all large modern scopes have such mountings.
Computer controlled mirrors have been designed
which can counteract the turbulence in the Earth's
atmosphere and give resolution close to the
theoretical limits.
Thanks to the wave nature of light, it is possible to
simulate a large telescope by combining the signals
from multiple dishes.
Such a telescope array does not have the light
gathering power of a full size telescope of the
same diameter. But it does have the same
resolving power.
The resolving power of a telescope is actually
a function of the size of the telescope and the
wavelength of light:
 = 1.22  / D
,
where is measured in radians and  and D are
measured in the same units of distance.
Since the wavelength of visible light is roughly
half a micron, the mirror must be ground and polished
to the right shape +/- a few percent of a micron, so
the mirror must be very rigid.
Radio waves have wavelengths of millimeters to
meters, so the radio dishes have to accurate to a tenth
of a millimeter to 10 cm. Thus, they can be made of
wire mesh and can be built to less exacting standards.
But in order to detect faint radio signals, radio
telescopes must be big.
NASA's Kuiper Airborne Observatory flew a 91-cm
telescope to altitudes as high as 45,000 feet. It
operated from 1975 to 1995.
The KAO could fly above the tallest mountain on
Earth, so could be used for infrared astronomy
impossible at ground-based observatories.
Astronomers and crew worked in a pressurized cabin,
while the telescope was effectively outside the plane.
X-ray and gamma-ray telescopes must operate outside
the Earth's atmosphere.
Optical and IR telescopes outside the Earth's atmosphere
reach their theoretical limits of resolution.